Computer apparatus, storage apparatus, system management apparatus, and hard disk unit power supply controlling method

ABSTRACT

To provide a storage system capable of minimizing a performance deterioration, saving power consumption, and realizing a high reliability. A storage system according to the present invention includes a computer, a storage apparatus  1  connected with the computer, and a storage management apparatus connected to the storage apparatus, the storage apparatus including a hard disk unit to control a data write operation and a data read operation between the computer and the hard disk unit, and control on/off states of power supply of the hard disk unit on a group basis, and the system management apparatus collecting running information about the computer and computer execution job information for each computer, and determining an on/off time of the power supply of the hard disk unit on the group basis to record the collected information and the on/off time of the power supply on the group basis.

The present application is based on and claims priority of Japanesepatent application No. 2005-288142 filed on Sep. 30, 2005, the entirecontents of which are hereby incorporated by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a storage apparatus system (hereinafteralso referred to as a “storage system”) for storing data of a computer(hereinafter also referred to as a “server”). In particular, the presentinvention relates to a storage apparatus composed of a plurality of harddisk units and a technique of controlling a power supply of theplurality of hard disk units.

2. Description of the Related Art

In recent years, various kinds of companies have found it necessary tosave all business documents or electronic mail in a storage system undervarious laws and regulations, and in addition, to enable prompt accessesto the stored data as needed.

A tape device that has been hitherto used as data storing means forstoring a large volume of data no longer satisfies a desire to allowprompt accesses to the stored data. Meanwhile, the tape deviceencounters a problem in that high fault rates occur and there is asignificant risk that data is lost or stolen during the conveyance of atape medium.

On the other hand, a hard disk having a SATA (serial advanced technologyattachment) interface has been put into widespread use as a hard diskfor a laptop personal computer, which is noted as an inexpensive harddisk compared to a hard disk using a fibre channel interface. Such ahard disk is loaded in place of the hard disk using the fibre channelinterface as a recording medium of the storage system, so a low-costlarge-capacity storage system can be provided.

With this as a backdrop, a large-capacity storage system equipped withseveral hundreds to one thousand SATA hard disk units has come intowidespread use as the large-capacity data storage means in place of thetape device.

However, the large-capacity storage system that has come into widespreaduse instead of the tape device is inferior to the tape device in powerconsumption. The power saving of the apparatus leads to reduction inoperating cost of the entire system, resulting in reduction of TCO(total cost of ownership) of the entire system. Some recent reportsreveal that the storage system consumes about 20 to 30% of the power ina data center, so how to save the power used for the apparatus becomesone of the biggest challenges for the future.

As a method for solving the above problems, Japanese Unexamined PatentApplication Publication No. Hei 09-282057 discloses a technique ofcontrolling on/off states of a power supply of an apparatus. Thistechnique controls the on/off states of the power supply of a peripheraldevice connected to a computer on the basis of the plan to execute a jobon the computer and the way to execute the job.

Further, as another method for solving the above problems, US Patent No.20040054939 and Japanese Unexamined Patent Application Publication No.2000-293314 disclose a technique of controlling on/off states of a powersupply of a hard disk loaded in a storage system. The technique of USPatent No. 20040054939 controls the power supply on the basis of harddisk in a hard disk group constituting a RAID. Further, in a productmanufactured with this technique, the number of hard disks running at atime is reduced to ¼ or less of the loaded hard disks (seehttp://www.copansys.com/pdfs/Revolution2000TDataSheet.pdf). Thetechnique of Japanese Patent Application Laid-open No. 2000-293314 turnsoff or saves the power of a power supply of a hard disk of a hard diskgroup constituting a RAID, which is not accessed.

As the power saving method for the storage system, the related art ofJapanese Unexamined Patent Application Publication No. Hei 09-282057only controls the on/off states of the power supply of the entireapparatus, and there is no description about details of the power supplycontrol such as the on/off control of the power supply of the individualhard disks loaded in the apparatus. This leads to a problem in that itis difficult to respond to an access request from a computer withoutdelay and a power-saving effect is not so large. There is no descriptionabout how to prevent the loss of reliability of the individual harddisks due to the repeated on/off operations of the power supply.

The related art of US Patent No. 20040054939 (seehttp://www.copansys.com/pdfs/Revolution2000TDataSheet.pdf) has a problemin that even when the requisite number of operating hard disks is lessthan ¼ of the loaded hard disks, it is impossible to expect apower-saving effect as high as an effect attained when the number ofoperating hard disks is far less than ¼ of the loaded hard disks. Inaddition, several hard disks that always operate are provided forresponding to the access request without delay, resulting in theincrease in power consumption.

The related art of Japanese Unexamined Patent Application PublicationNo. 2000-293314 is such a passive power supply controlling method thatthe power supply of the hard disk is turned off when there is no access.Hence, it is difficult to respond to the access request without delay.There is no description about how to prevent the loss of reliability ofthe individual hard disks due to the repeated on/off operations of thepower supply.

SUMMARY OF THE INVENTION

The present invention has been accomplished to solve the aforementionedproblems, and accordingly it is an object of the present invention toprovide a computer system, including: a plurality of computers; astorage apparatus having a plurality of hard disk units and beingconnected to the plurality of computers; and a system managementapparatus connected to the plurality of computers and the storageapparatus, the storage apparatus controlling a data write operation anda data read operation between the computers and the hard disk units, andcontrolling on/off states of a plurality of power supplies of theplurality of hard disk units on a group basis with the group includingone or more hard disk units, and the system management apparatuscollecting running information about the plurality of computers andcomputer execution job information for each computer, and determining anon/off time of the power supplies of the plurality of hard disk units onthe group basis to record the collected information and the on/off timeof the power supplies on the group basis.

According to the present invention, it is possible to provide a storageapparatus capable of minimizing a performance deterioration, saving thepower and prolonging the lifetime of the hard disk loaded to theapparatus to enhance the reliability of the apparatus.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a configuration example of a storage apparatus, and acomputer apparatus and a management server connected to the storageapparatus according to an embodiment of the present invention;

FIG. 2 shows an example of a computer running schedule table;

FIG. 3 shows an example of an execution script;

FIG. 4 shows a mapping example between volumes allocated to a computerand RAID Gr.;

FIG. 5 shows an example of a RAID Gr. power supply control scheduletable;

FIG. 6 is a flowchart illustrative of an example of a procedure forcreating the RAID Gr. power supply control schedule table;

FIG. 7 is a flowchart illustrative of an example of a procedure forsetting limits on the number of simultaneous running RAID Gr. during thecreation of the RAID Gr. power supply control schedule table;

FIG. 8 is a flowchart illustrative of an example of a procedure forsetting limits for improving the performance during the creation of theRAID Gr. power supply control schedule table;

FIG. 9 shows another configuration example of the storage apparatus andthe computer and management server connected to the storage apparatus;

FIG. 10 is a flowchart illustrative of an example of a procedure forcorrecting the RAID Gr. power supply control schedule table during therunning of the computer;

FIG. 11 is a flowchart illustrative of an example of a procedure forsetting limits on the number of times the power supply of the RAID Gr.is turned on/off during the creation of the RAID Gr. power supplycontrol schedule table;

FIG. 12 shows a physical location example of the simultaneous runningRAID Gr. in a hard disk rack;

FIG. 13 shows another physical location example of the simultaneousrunning RAID Gr. in a hard disk rack;

FIG. 14 shows an example of a table listing physical locations of theRAID Gr. in the hard disk rack; and

FIG. 15 shows an example of a table listing combinations of computersthe number of simultaneous running RAID Gr. of which exceeds the upperlimit when the computers run at a time.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Hereinafter, the best modes for carrying out the invention will bedescribed.

A computer system, a storage apparatus, a system management apparatus,and a hard disk unit power supply controlling method according toembodiments of the present invention are described with reference to theaccompanying drawings.

First Embodiment

A first embodiment of the present invention is described below. FIG. 1shows a configuration example of a system including a storage apparatusaccording to the first embodiment of the present invention. The systemincludes a storage apparatus 1, a storage management server 2, acomputer 3, and a computer management server 4. The storage managementserver 2 and the computer management server 4 constitute a systemmanagement apparatus. As shown in FIG. 1, the storage apparatus 1 andthe computer 3 are directly connected but may be connected through aswitch. One or more computers 3 may be provided and composed of aplurality of virtual machines.

The storage apparatus 1 includes a controller 11 and a hard disk loadingunit (hard disk unit) 31. The controller 11 includes a channel IF(interface) unit 12 connected to the computer 3 to control datawrite/read accesses from the computer 3, a disk IF (interface) unit 13connected with a plurality of hard disks 32 to control data write/readaccesses to the hard disks 32, a cache memory 14 temporarily storingwrite/read data with respect to the hard disks 32, and a connectionportion connecting among the channel IF unit 12, the disk IF unit 13,and the cache memory 14. The connection portion 15 is generally composedof a plurality of switches but may be composed of several common buslines.

The channel IF unit 12 controls the data transfer from/to the cachememory 14 in response to the data write/read access from the computer 3.The disk IF unit 13 controls the data transfer from/to the cache memory14 upon writing/reading the data to/from the hard disks 32. Due to suchdata exchange of the channel IF unit 12 and the disk IF unit 13 throughthe cache memory 14, the computer 3 writes/reads data to the hard disk14. In order to execute such control, the channel IF unit 12 and thedisk IF unit 13 include one or more processors (not shown). Theprocessors are connected with an internal LAN 17. Further, a storagemanagement server 2 provided outside the storage apparatus is connectedto the internal LAN 17.

Here, the configuration of the above controller 11 is illustrated by wayof example, and the configuration is not limited to the above one. Thecontroller 11 may have any configuration insofar as a function ofwriting/reading data to/from the hard disks 32 can be executed.

The controller 11 further includes a power supply control unit 16 forcontrolling on/off (power-on, power-off) states of the power supply ofthe hard disks 32. The power supply control unit 16 is connected to theinternal LAN 17.

The hard disk loading unit 31 includes the plurality of hard disks 32and a hard disk power supply 33 for supplying power to the individualhard disks 32. The plurality of hard disks 32 are grouped into a RAIDgroup (Gr.). Here, for example, one or two (in the case of redundantconfiguration) hard disk power supplies 33 may be provided for each harddisk 32 or RAID Gr.

The power supply control unit 16 of the controller 11 is connected tothe hard disk power supply 33 to control the on/off states of the powersupply. Here, the power supply control unit 16 may be provided insidethe hard disk loading unit 31, not inside the controller 11. Further,the power supply control unit 16 may be directly connected to thestorage management server 2.

The computer management server 4 includes a computer running scheduler40 for determining a start time and stop time for each computer,computer running information summarizing the computer start time andstop time for each computer, and computer execution job information 42serving as information about a job executed on each computer. The jobsare independent of each other, so the processings executed by aplurality of computers may be referred to as a job.

The storage management server 2 includes a computer running informationcollection unit 21 for collecting computer running information 41 fromthe computer management server 4, a computer execution job informationcollection unit 22 for collecting the computer execution job information42, a RAID Gr. running scheduler 24 for scheduling the on/off time ofthe power supply for each RAID Gr., and a memory 23 for storing acomputer running schedule table 231 created on the basis of the computerrunning information 41 collected from the computer management server 4,volume input/output information 232 created on the basis of the computerexecution job information 42, and a RAID Gr. power supply controlschedule table 233 created with the RAID Gr. running scheduler 24 on thebasis of the computer running schedule table 231 and the volumeinput/output information 232.

The power supply control unit 16 receives the RAID Gr. power supplycontrol schedule table 233 from the storage management server 2 tocontrol the hard disk power supply 33 in accordance with the schedule ofthe table.

FIG. 2 shows an example of the computer running schedule table 231. Thecomputer running information collection unit 21 collects the start timeand stop time for each computer from the computer management server 4 tocreate a table listing the start time (Start) and stop time (Stop) ofeach computer as shown in the figure. Alternatively, the start time andrun time of each computer may be collected from the computer managementserver 4 to derive the stop time based on the start time and the runtime.

Here, the format of the computer running schedule table 231 of FIG. 2 isillustrated by way of example, and the format is not limited to theabove one. Any format can be used as long as the start time and stoptime of each computer 3 can be known.

FIG. 3 shows an example of an execution script 234 that describesinformation about an execution job (or calculation) to be executed oneach computer 3. The execution script 234 is input with a terminal (notshown) connected with the computer management server 4 by a user whoexecutes computation using the computers 3 and stored in the computerexecution job information 42. The execution script 234 is provided foreach computer 3, and in the illustrated example, a plurality ofexecution scripts are provided. In order to draw up the power supplycontrol schedule of the hard disk 32 on the storage apparatus 1, theexecution script 234 includes information 300 about a logical volume(LU) for storing at least a computation parameter or computation result.

Further, a run time (CPU TIME) 301, an execution repetitive number 302,and a repetitive number in an interval 303 for outputting thecomputation result are preferably provided. Such information enablefiner power supply control of the hard disks 32.

Here, the format of the execution script of FIG. 3 is illustrated by wayof example, and the format is not limited to that of FIG. 3. Any formatmay be used as far as at least the above information is included.

FIG. 4 shows an example of a computer-volume (LU)-RAID Gr. mapping 235indicative of mapping between the logical volume (LU) allocated to acomputer and RAID Gr. to which the logical volume belongs. The storagemanagement server 2 includes a mapping table illustrative of mappingbetween the logical volume, which is provided to the computer by thestorage apparatus 1, and the RAID Gr. One or more logical volumes areallocated to each computer 3. Upon executing some computation, thecomputer 3 uses not all the allocated logical volumes. Therefore, thecomputer execution job information collection unit 22 extracts logicalvolume information used by each computer for the computation from theexecution script 234 collected from the computer management server 4 tocreate the computer-volume (LU)-RAID Gr. mapping 235.

In the computer-volume (LU)-RAID Gr. mapping 235 of FIG. 4, an itemindicating whether or not each logical volume is used for computationmay be added to define the computer-volume (LU)-RAID Gr. mapping for allthe logical volumes allocated to the computer 3. Thus, a table showingwhether or not each logical unit is used for computation may be created.

FIG. 5 shows an example of the RAID Gr. power supply control scheduletable 233. The RAID Gr. running scheduler 24 creates a table showing thepower-on time (power ON) and power-off time (power OFF) for each RAIDGr. on the basis of the computer running information 41 collected withthe computer running information collection unit 21 and the computerexecution job information 42 collected with the computer execution jobinformation collection unit 22.

Here, the format of the RAID Gr. power supply control schedule table 233is illustrated by way of example, and the format is not limited to theabove format of FIG. 5. Any format can be used as long as the power-ontime and the power-off time can be known for each RAID Gr.

FIG. 6 is a flowchart illustrative of an example of a procedure forcreating the RAID Gr. power supply control schedule table 233 in thestorage management server 2. First, the computer running informationcollection unit 21 collects the computer running information 41 asrunning information of each computer 3 from the computer managementserver 4 (401). The computer execution job information collection unit22 collects the execution script 234 from the computer management server4 as the computer execution job information 42 (402). The computerrunning information collection unit 21 creates the computer runningschedule table 231 on the basis of the collected computer runninginformation 41 to store the created table in the memory 23 (403). If thecomputer running information 41 includes a table similar to the computerrunning schedule table 231, the table may be used as it is. The computerexecution job information collection unit 22 extracts from the collectedexecution script 234 the logical volume 300 used for the computation tocreate the computer-volume (LU)-RAID Gr. mapping 235 on the basis of therelation between the logical volume and the RAID Gr, which is in thestorage management server 2. (404).

Next, a RAID Gr. power supply control schedule table 1 (233) is createdon the basis of the logical volume allocated to each computer, the RAIDGr. to which the logical volume belongs, and the start time and stoptime of each computer derived from the computer running schedule table231 (405).

Hereinbelow, a description is made of an example of the way to determinethe on/off time of the RAID Gr. power supply necessary for creating thepower supply control schedule table 1 (233). For reading data necessaryfor the computation from the allocated logical volume at the start ofrunning the computer, the logical volume needs to be in an operatingstate. Then, for writing the computation result to the allocated volumeat the end of running, the logical volume needs to be in an operatingstate. The operating period of the logical volume should be set notshorter than a period necessary for the computer to read data and notshorter than a period necessary for the computer to write the data. Theamount of read/write data varies depending on the conditions for theexecuted computation, but never exceeds the capacity of the logicalvolume to/from which the data is written/read. Hence, the logical volumeoperating period for the data write or read is set to the sum of aperiod necessary for reading or writing data corresponding to thecapacity of the logical volume and a period set as a margin that iscalculated at a given rate (for example, about 10% of the total period).

Here, the size of the data read from the logical volume at the start ofcomputation and the size of the data written to the logical volume atthe end of completion are described in the execution script 234, makingit possible to more accurately determine the logical volume operatingperiod.

The data read or write speed can be derived as an average value from theperformance records of the storage apparatus, making it possible tocalculate a period necessary for reading data at the start ofcomputation and a period necessary for writing data at the end ofcomputation on the basis of the average speeds and the volume capacitywith the use of the aforementioned method.

After the power-on of the hard disk, it takes several minutes to allowthe data read/write. Thus, it is necessary to turn on the power supplyof the hard disk several minutes before the start time or stop time.Therefore, the start time of the data reading logical volume allocatedto any computer is several minutes ahead of the start time of thecomputer (requisite period from the power-on of the hard disk until whenthe read operation is allowed). The logical volume operation stop timeis set to a time after the time necessary for reading data that isdetermined with the above method. Further, if the computation startsafter all the data have been read, the logical volume may operate asearly as the above-mentioned several minutes plus the time necessary forreading data. In this case, the logical volume operation stop time maybe set to the start time or set several minutes behind the start timewith time to spare. Likewise, the operating start time for the datawriting logical volume allocated to any computer is set several minutesahead of the stop time of the computer (period from the power-on of thepower supply of the hard disk until when the data write is allowed). Thelogical volume operation stop time is set to a time after the timenecessary for writing data that is determined with the above method,from the stop time of the computer. Here, if the data reading logicalvolume and the data writing logical volume are the same, needless tosay, the time calculated with the above method upon the datareading/writing may be set to the logical volume operating start timeand stop time.

In this way, a pair of operating start time and stop time are calculatedfor all the logical volumes used by the computer 3 for the calculation(needless to say, there are a number of pairs). The relation between thelogical volumes and the RAID Gr. can be known on the basis of thecomputer-volume (LU)-RAID Gr. mapping 235. Hence, the power supplyon/off time of the RAID Gr. necessary for creating the RAID Gr. powersupply control schedule table 1 (233) can be determined based on thepairs of operating start time and stop time for all the logical volumesused by the computer 3 for the computation.

Next, the run time 301, the execution repetitive number 302, and therepetitive execution interval 303 for outputting the computation resultare extracted from the execution script 234 to calculate the calculationresult output time to the RAID Gr. to which the logical volume allocatedto a computer belongs on the basis of the extracted information tocreate the RAID Gr. power supply control schedule table 2 (233) (406).

Hereinbelow, a description is made of an example of the way to determinethe on/off time of the RAID Gr. power supply of the RAID Gr. necessaryfor creating the RAID Gr. power supply control schedule table 2 (233).The time necessary for one computation cycle can be derived from the runtime 301 and the execution repetitive number 302 extracted from theexecution script 234. Further, the time interval for outputting thecomputation result can be derived from the time necessary for onecomputation cycle and the repetitive number in an interval 303 foroutputting the computation result. It is possible to determine theoperating start time and stop time of the logical volume to which theintermediate computation result is output on the basis of the timeinterval for outputting the computation result.

The logical volume is made to operate at the time intervals foroutputting the computation result from the start time of the computer.Further, it is possible to determine the logical volume operating periodsimilar to the method described in the section about the way todetermine the power supply on/off time of the RAID Gr. necessary forcreating the RAID Gr. power supply control schedule table 1 (233).Further, it takes several minutes to allow the data reading/writing fromthe power-on of the power supply of the hard disk. Hence, the powersupply of the hard disk should be turned on several minutes ahead of thecomputation result output time. Based on these, the operating start timeand stop time of the logical volume to which the intermediatecomputation result is output can be determined.

In this way, a pair of operating start time and stop time are calculatedfor all the logical volumes to which the intermediate computation resultis output by use of the computer 3 (needless to say, there are variouspairs). The relation between the volume (LU) and RAID Gr. can be knownon the basis of the computer-volume (LU)-RAID Gr. mapping 235. Hence,the power supply on/off time of the RAID Gr. necessary for creating theRAID Gr. power supply control schedule table 2 (233) can be determinedbased on the pairs of operating start time and stop time for all thelogical volumes to which the intermediate computation result is output.

Next, the RAID Gr. power supply control schedule table 1 (233) iscombined with the RAID Gr. power supply control schedule table 2 (233)to create a RAID Gr. power supply control schedule table 3 (233) (407).In combining the two tables, needless to say, portions of tables 1 and 2where the power-on times overlap for all the logical volumes used forcomputation need to be combined, and the power-on time and the power-offtime should be adjusted.

Herein, the RAID Gr. power supply control schedule is predicted anddetermined as mentioned above, but the input/output time of the datato/from the computer 3 may be shifted from the predicted time. In orderto allow the data input/output even in such a case, the storageapparatus 1 has the following function.

In the case where the data input/output time is moved ahead of thepredicted time, and the power supply of the corresponding RAID Gr. isturned off, an instruction to stop and wait the data writing/reading isissued to the computer 3. If the data input/output time is delayed fromthe predicted time, the power supply is kept on until the datainput/output is completed instead of turning off the power supply of theRAID Gr. at the predicted time. At this time, if the next power-on timeof the RAID Gr. is passed, the power supply is kept on until the powersupply off time corresponding to the power supply on time.

Further, if the data input/output time is moved ahead of the predictedtime, the power supply of the RAID Gr. is turned off, and the datawriting operation is executed, the following control can be executed.That is, if a capacity of a temporarily storable area in the cachememory 14 of the storage apparatus 1 is larger than the amount of datawritten during the activation period of the hard disk, the data writerequest is accepted; otherwise, the computer 3 is instructed to stop andwait the data writing.

According to this embodiment, the power supply of the hard diskcomposing the RAID Gr. to which a logical volume belongs can be turnedon in accordance with the data input/output time for the logical volumeof the storage apparatus 1 allocated to the computer 3, and the powersupply of the hard disk can be turned off in accordance with the datainput/output stop time. Hence, the input/output performancedeterioration of the storage apparatus 1 can be minimized, and the powerconsumption of the apparatus can be reduced.

This embodiment describes the case where the power on/off states of thehard disk 32 are controlled to save the power consumption of the storageapparatus 1. However, it is also possible to use the hard disks 32operable with various rotational speeds as a data storage medium. Inthis case, the power supply control unit 16 has a function ofcontrolling the rotational speed as well as the on/off states of thepower supply.

The use of the hard disks 32 operable with various rotational speedsrealizes more efficient power saving with less deterioration inperformance than the case of executing only the on/off control.

FIG. 7 shows an example of a method for further reducing powerconsumption in the storage apparatus 1 of this embodiment. The RAID Gr.power supply control schedule table 233 is first created in accordancewith the procedure illustrated in FIG. 6.

Next, the time zone where the number of simultaneous running RAID Gr.exceeds an upper limit is retrieved from the RAID Gr. power supplycontrol schedule table 233 (501).

If there is a time zone where the number exceeds the upper limit, anumber of RAID Gr. exceeding the upper limit of the predetermined numberof simultaneous running RAID Gr. are selected. The selection isperformed in order from the RAID Gr. with the minimum number ofsimultaneous operating logical volumes out of the target simultaneousrunning RAID Gr. (502). Herein, the selection method is given by way ofexample, and the present invention is not limited to this method.

Next, the controller 11 is notified of the simultaneous running RAID Gr.concerned, the selected simultaneous running RAID Gr. beyond the upperlimit of the predetermined number of simultaneous running RAID Gr., andthe simultaneous operating logical volumes of the selected RAID Gr.(503).

The notified controller 11 reallocates the simultaneous operatinglogical volumes of the selected RAID Gr. informed by the storagemanagement server 2 to the simultaneous running RAID Gr. other than theselected RAID Gr. to transfer the data in the reallocated logicalvolumes to the RAID Gr. having been designated as the reallocationdestination. (504).

After that, the processing returns to step 502 to repeat steps 502 to504 until it is confirmed that there is no time zone where the number ofsimultaneous running RAID Gr. exceeds the upper limit.

Then, if it is confirmed that there is no time zone where the number ofsimultaneous running RAID Gr. exceeds the upper limit, the RAID Gr.power supply control schedule table 233 is corrected on the basis of theinformation about the relocated logical volume (505).

If there still remains the time zone where the number of simultaneousrunning RAID Gr. exceeds the upper limit, the repeating of steps 502 to504 is stopped at the time when a difference between the number ofsimultaneous running RAID Gr. and the upper limit is minimized.

According to the above method, the number of simultaneous running RAIDGr. can be set to a predetermined value or less, so the powerconsumption can be saved more than the case where the number ofsimultaneous running RAID Gr. is not limited.

FIG. 8 shows an example of a method of improving the data input/outputperformance and prolonging the lifetime of the hard disk in the storageapparatus 1 of this embodiment. The RAID Gr. power supply controlschedule table 233 is first created in accordance with the procedureillustrated in FIG. 6. Next, a RAID Gr. in which a time interval fromthe power-off to the power-on is shorter than a predetermined period isretrieved from the RAID Gr. power supply control schedule table 233(601).

If the RAID Gr. in which a time interval from the power-off to thepower-on is shorter than a predetermined period is found, the power-offtime and subsequent power-on time of the RAID Gr. are deleted from theportion corresponding to the time interval of the RAID Gr. in the RAIDGr. power supply control schedule table 233 to execute such correctionthat the power supply of the RAID Gr. is turned on during thecorresponding time interval (602). The process of step 602 is repeateduntil it is confirmed that there is no RAID Gr. where the time intervalfrom the power-off to the power-on is shorter than a predeterminedperiod to end the processing (603).

According to the above method, it is possible to prevent the powersupply of the RAID Gr. from being turned on/off more than necessary,making it possible to improve the data input/output performance, andprolong the lifetime of the hard disk.

FIG. 10 shows an example of a method for correcting the RAID Gr. powersupply control schedule table 233 during the running of the computer inthe storage apparatus 1 of this embodiment.

As shown in FIG. 9, the computer management server 4 includes a runningstate monitor 43 for monitoring the running state of each computer andrunning state information 44 representing the monitoring result. Therunning state information 44 includes at least the elapsed time from thestart time and the repetitive computation number. The running statemonitor 43 periodically monitors the elapsed time from the start timeand the repetitive computation number at predetermined time intervals.

As shown in FIG. 10. the computer execution job information collectionunit 22 in the storage management server 2 makes an inquiry to thecomputer management server 4 at predetermined time intervals to therebyreceive the elapsed time from the start time and the repetitivecomputation number from the run state information 44 (701).

Next, the computer execution job information collection unit 22recalculates the data input/output time to/from the logical volume usedby the computer for the current time and subsequent time on the basis ofthe elapsed time from the start time and the repetitive computationnumber (702). Based on the calculation result, the data input/outputtime of the RAID Gr. to which the logical volume used by the computerbelongs is recalculated as illustrated in FIG. 6 (703).

Next, it is checked whether or not the recalculated schedule matcheswith the RAID Gr. power supply control schedule table 233 created uponthe initial setting or a previous correction (704).

If not matched, the RAID Gr. power supply control schedule table 233 iscorrected (705). If matched, the system waits for the next correctiontime.

According to the above method, it is possible to control the on/offstates of the power supply of the RAID Gr. in sync with the actual datainput/output time to/from the computer.

FIG. 11 shows an example of a method for setting limits on the number oftimes the power supply of the RAID Gr. is turned on/off in the storageapparatus 1 of this embodiment.

The power supply control unit 16 in the controller 11 counts the numberof times the power supply is turned on/off for each RAID Gr.

If the computer completes all the computations in accordance with therunning schedule, and draws up the new running schedule to start thecalculation, the storage management server 2 creates the RAID Gr. powersupply control schedule table 233 in accordance with the procedureillustrated in FIG. 6 on the basis of the new running schedule.

Next, the RAID Gr. running scheduler 24 of the storage management server2 receives the number of on/off operations of the power supply of allthe RAID Gr. in the storage apparatus 1 from the power supply controlunit 16 (801).

Next, in the RAID Gr. power supply control schedule table 233, the RAIDGr. where the number of power on/off operations during a given periodexceeds a predetermined value is searched (802).

If there is found the RAID Gr. where the number of power on/offoperations during a given period exceeds a predetermined value, the RAIDGr. with a smaller number of power on/off operations is searched (803).As an example of selecting the RAID Gr. with a smaller number of poweron/off operations, a given number of RAID Gr. are selected in order fromthe RAID Gr. with the minimum number of power on/off operations. Here,the selecting method is given by way of example, and the presentinvention is not limited to this method.

Next, the controller 11 is notified of the corresponding RAID Gr., thesimultaneous operating logical volumes in the corresponding RAID Gr.,and the selected RAID Gr. with a smaller number of on/off operations(804).

Next, the controller 11 reallocates the simultaneous operating logicalvolumes of the corresponding RAID Gr. informed by the RAID Gr. runningscheduler 24 to the selected RAID Gr. with a smaller number of on/offoperations to transfer the data in the reallocated logical volumes tothe RAID Gr. having been designated as the reallocation destination(805).

If there is no RAID Gr. where the number of power on/off operationsexceeds a predetermined value, the system waits for the creating of thenext RAID Gr. power supply control schedule table 233.

According to the above method, it is possible to prolong the lifetime ofthe hard disks to raise the reliability of the storage apparatus 1.

FIGS. 12 and 13 show an example of a method of suppressing thetemperature increase due to the heat of the running hard disk in thestorage apparatus 1 of this embodiment. In the hard disk rack 170, thehard disks 32 are incorporated in a hard disk enclosure 172 and thusloaded. A power supply 171 is provided at the lower portion of the harddisk rack 170.

As shown in FIGS. 12 and 13, the hard disks 32 are collectively arrangedfor each RAID Gr. 34 so that the RAID Gr. 34 composed of the hard disks192 at rest surround the RAID Gr. 34 composed of the running hard disk191. With such arrangement, the heat is dispersed to prevent the ambienttemperature of the hard disk from increasing.

The storage management server 2 includes information for specifying thephysical location of the RAID Gr. of the storage apparatus 1 in the harddisk rack 170. FIG. 14 shows an example of a table illustrative of therelation between the physical locations and the RAID Gr., that is, theRAID Gr.-physical location mapping. The vertical locations in the harddisk rack 170 of FIGS. 12 and 13 are numbered from the top like a, b, c,. . . , and the horizontal locations are numbered from the left like 1,2, . . . . With such numbering, the RAID Gr. number is mapped with thephysical locations as shown in the table of FIG. 14.

Here, the table of FIG. 14 is illustrated by way of example, and thepresent invention is not limited to this relation between the RAID Gr.and the physical location. Any other tables may be used insofar as thephysical location of each RAID Gr. in the hard disk rack can bespecified.

The RAID Gr. running scheduler 24 of the storage management server 2searches the table of FIG. 14 for the simultaneous running RAID Gr.whose locations in the hard disk rack 170 are adjacent vertically,back-and-fourth, and horizontally. If adjacent RAID Gr. are found, thecontroller 11 is notified of the corresponding RAID Gr., the othersimultaneous running RAID Gr., and the simultaneous operating logicalvolumes of the corresponding RAID Gr. Then, the controller 11reallocates the simultaneous operating logical volumes of the RAID Gr.with a smaller number of simultaneous operating logical volumes out ofthe adjacent RAID Gr. notified by the RAID Gr. running scheduler 24 tothe simultaneous running RAID Gr. other than the adjacent RAID Gr. totransfer the data in the allocated logical volume to the RAID Gr. havingbeen designated as the reallocation destination.

According to the above method, it is possible to suppress thereliability drop of the hard disk due to the heat and improve thereliability of the storage apparatus 1.

Second Embodiment

Subsequently, a second embodiment of the present invention is described.In this embodiment, the storage management server 2 allocates thelogical volumes to each computer 3. The logical volumes are retrievedfrom the RAID Gr. composed of the plurality of hard disks 32 andallocated to the computers 3. Therefore, after the logical volumes areallocated to the computers 3, the computer-volume (LU)-RAID Gr. mapping235 as shown in FIG. 4 can be created.

Based on this table, when one or more pairs of computers simultaneouslyoperate, it is possible to determine how may RAID Gr. are simultaneouslyoperated and which RAID Gr. is simultaneously operated. Thisdetermination is carried out for all the combinations of computers, sothe combinations of the computers can be retrieved when the RAID Gr.larger than a predetermined number of RAID Gr. simultaneously operate.FIG. 15 is a table showing an example of the retrieval result. Asimultaneous running RAID Gr.-computer combination mapping 285 shows thesimultaneous running RAID Gr. number and the number of simultaneousrunning RAID Gr. for all the combinations of computers, and includes anitem indicative of a combination of computers corresponding to thenumber of simultaneous running RAID Gr. exceeding the predeterminednumber of simultaneous running RAID Gr.

The table is sent to the computer management server 4, and the computermanagement server 4 can display the combination of computers where thenumber of simultaneous running RAID Gr. exceeds the predetermined numberof simultaneous running RAID Gr. on a display device (not shown)connected with the server. Thus, the running schedule can be so adjustedas to avoid the combination of computers by means of a user'sinstruction or a program run on the computer management server 4.

Further, after the computer running schedule is set, it is possible todisplay the combination of computers where the number of simultaneousrunning RAID Gr. exceeds the predetermined value to let a user changethe computer running schedule or to automatically change the runningschedule in such a way that the number of simultaneous RAID Gr. neverexceeds the predetermined value by use of the program run on thecomputer management server 4.

The above description has been made based on the embodiments of thepresent invention.

In a first modification of the embodiment, the storage apparatus is acomputer system for turning on/off the power supply of the plurality ofhard disk units using the power on/off time on the group basis which isrecorded by the system management apparatus.

In a second modification of the embodiment, the storage apparatusdefines one or more logical storage areas using the hard disk unitgroup, and allocates the storage areas to the plurality of computers,and the system management apparatus extracts the storage areas allocatedto the plurality of computers from the computer execution jobinformation and extracts the hard disk unit group having the storageareas to create a first hard disk unit group power supply controlschedule table using information about the storage areas allocated tothe plurality of computers, information about the hard disk unit grouphaving the storage areas, and a start time and stop time of thecomputer.

In a third modification of the embodiment, the system managementapparatus extracts the start time and stop time of each computer fromthe running information of the plurality of computers.

In a fourth modification of the embodiment, the system managementapparatus extracts a run time, a repetitive computation number, and aninterval for outputting a computation result from the computer executionjob information, and calculates an output time for the computationresult to the hard disk unit group to which the storage area allocatedto each of the plurality of computers belongs on the basis of theextracted information to create a second hard disk unit group powersupply control schedule table.

In a fifth modification of the embodiment, the system managementapparatus combines the first hard disk unit group power supply controlschedule table with the second hard disk unit group power supply controlschedule table to create a third hard disk unit group power supplycontrol schedule table.

In a sixth modification of the embodiment, the system managementapparatus searches for a time zone in which simultaneous running harddisk unit groups exceeding a predetermined number of simultaneousrunning hard disk unit groups run on the basis of the third hard diskunit group power supply control schedule table, extracts a correspondingtime zone, corresponding simultaneous running hard disk unit groups, andsimultaneous operating logical storage areas in the simultaneous runninghard disk unit groups, selects a number of simultaneous running harddisk unit groups that has exceeded the predetermined number ofsimultaneous running hard disk unit groups from among the simultaneousrunning hard disk unit groups, and notifies the storage apparatus of theextracted simultaneous running hard disk unit groups, the selectednumber of simultaneous running hard disk unit groups that has exceededthe predetermined number of simultaneous running hard disk unit groups,and simultaneous driven logical storage areas in the simultaneousrunning hard disk unit groups, and the storage apparatus reallocates thesimultaneous operating logical storage areas in the selected number ofsimultaneous running hard disk unit groups that has exceeded thepredetermined number of simultaneous running hard disk unit groups,which is notified by the system management apparatus, to a simultaneousrunning hard disk unit group other than the selected number ofsimultaneous running hard disk unit groups that has exceeded thepredetermined number of simultaneous running hard disk unit groups totransfer data in the reallocated logical storage areas to the hard diskunit group having been designated as the reallocation destination.

In a seventh modification of the embodiment, when the number ofsimultaneous running hard disk unit groups that has exceeded thepredetermined number of simultaneous running hard disk unit groups areselected, the system management apparatus preferentially startsselection from a hard disk unit group with the minimum logical storagearea out of the corresponding simultaneous running hard disk unitgroups.

In an eighth modification of the embodiment, the system managementapparatus searches for a hard disk unit group in which a time periodfrom power-on to power-off is shorter than a predetermined time on thebasis of the third hard disk unit group power supply control scheduletable, and if a hard disk unit group in which a time period frompower-on to power-off is shorter than the predetermined time is found,corrects the third hard disk unit group power supply control scheduletable such that the power supplies of the hard disk unit groups in aportion of the schedule table corresponding to the time interval areturned on.

In a ninth modification of the embodiment, the system managementapparatus obtains an elapsed time from a job start time of an executionjob and a repetitive computation number from the computers that areexecuting computation to calculate a calculation result output time toeach of the hard disk unit groups from a current time onward on thebasis of the elapsed time and the repetitive computation number tocorrect the third hard disk unit group power supply control scheduletable on the basis of the calculated computation result output time.

In a tenth modification of the embodiment, the system managementapparatus obtains the number of on/off operations for each of the harddisk unit groups to search for a hard disk unit group in which thenumber of on/off operations for each of the hard disk unit groupsexceeds a predetermined value for each of the hard disk unit groups, andif a hard disk unit group in which the number of on/off operations foreach of the hard disk unit groups exceeds the predetermined value isfound, notifies a control unit of a corresponding hard disk unit group,and a simultaneous operating logical storage area in the correspondinghard disk unit group, and the storage apparatus reallocates thesimultaneous operating logical storage area in the hard disk unit groupnotified by the system management apparatus to a hard disk unit groupother than the notified hard disk unit group to transfer data in thereallocated logical storage area to the other hard disk unit group.

In an eleventh modification of the embodiment, the system managementapparatus searches for hard disk unit groups whose locations in a rackincorporating a hard disk unit group are adjacent vertically,back-and-fourth, and horizontally, from among the simultaneous runninghard disk unit groups, and if the hard disk unit groups whose locationsin the rack incorporating the hard disk unit group are adjacent arefound, notifies the storage apparatus of a corresponding hard disk unitgroup, and a simultaneous operating logical storage area in the harddisk unit group, and the storage apparatus reallocates the simultaneousoperating logical storage area in the hard disk unit group notified bythe system management apparatus to a hard disk unit group other than thenotified hard disk unit group to transfer data in the reallocatedlogical storage area to the hard disk unit group having been designatedas the reallocation destination.

In a twelfth modification of the embodiment, when the plurality ofcomputers operate, the system management apparatus calculates the pairsof simultaneous operating computers and the number of hard disk unitgroups that will run simultaneously with the operating computers in thecase of operating the computers for two or more combinations of theplurality of computers to display the calculation result.

In a thirteenth modification of the embodiment, the system managementapparatus checks whether or not there is a combination of simultaneousoperating computers with simultaneous running hard disk unit groups thatexceeds a predetermined value, and if the combination of thesimultaneous operating computer is found as a result of the checking,displays the combination of simultaneous operating computers, and if notfound, displays that no corresponding combination of simultaneousoperating computers is found.

In a fourteenth modification of the embodiment, the storage apparatusincorporates the system management apparatus.

In a fifteenth modification of the embodiment, a system managementapparatus includes: a storage apparatus having a plurality of hard diskunits, a storage apparatus for controlling a data write operation and adata read operation between a plurality of computers and the hard diskunits and for controlling on/off states of a plurality of power suppliesof the plurality of hard disk units on a group basis, wherein the systemmanagement apparatus is connected to the plurality of computers, andcollecting running information about the plurality of computers andcomputer execution job information for each computer, and determining anon/off time of the power supplies of the plurality of hard disk units onthe group basis to record the collected information and the on/off timeof the power supplies on the group basis.

In a sixteenth modification of the embodiment, the system managementapparatus is a computer management server and a storage managementserver.

In a seventeenth modification of the embodiment, a storage apparatusincludes a plurality of hard disk units, the apparatus being connectedto a plurality of computers and a system management apparatus,controlling a data write operation and a data read operation between theplurality of computers and the plurality of hard disk units, andcontrolling on/off states of a plurality of power supplies of theplurality of hard disk units on a group basis with the group includingone or more hard disk units to turn on/off the power supplies of theplurality of hard disk units using a power on/off time recorded by thesystem management apparatus on the group basis.

In an eighteenth modification of the embodiment, the system managementapparatus is incorporated in the storage apparatus.

In a nineteenth modification of the embodiment, a hard disk unit powersupply controlling method for controlling a plurality of power suppliesof a plurality of hard disk units of a storage apparatus in a computersystem including a plurality of computers, the storage apparatusconnected with the plurality of computers and having the plurality ofhard disk units and a system management apparatus connected to thestorage apparatus includes: controlling on/off states of the pluralityof power supplies of the plurality of hard disk units on a group basiswith the group including one or more hard disk units; collecting runninginformation about the plurality of computers and computer execution jobinformation for each computer; determining an on/off time of the powersupplies of the plurality of hard disk units on the group basis torecord the collected information and the on/off time of the powersupplies on the group basis; and controlling the on/off states of thepower supplies of the hard disk units using the recorded on/off time ofthe power supplies on the group basis.

1. A computer system, comprising: a plurality of computers; a storageapparatus having a plurality of hard disk units and being connected tothe plurality of computers; and a system management apparatus connectedto the plurality of computers and the storage apparatus, wherein thestorage apparatus controls a data write operation and a data readoperation between the computers and the hard disk units, and controlsrotational speeds of data storage media of the plurality of hard diskunits on a group basis with the group including one or more hard diskunits, and wherein the system management apparatus collects runninginformation about the plurality of computers and computer execution jobinformation for each computer, and determines various rotational speedsof the data storage media of the plurality of hard disk units on thegroup basis to record the collected information and the variousrotational speeds on the group basis.
 2. The computer system accordingto claim 1, wherein the storage apparatus controls the rotational speedsof the data storage media of the plurality of hard disk units using thevarious rotational speeds recorded by the system management apparatus onthe group basis.
 3. The computer system according to claim 1, whereinthe storage apparatus defines one or more logical storage areas usingthe group of the hard disk units, and allocates the storage areas to theplurality of computers, and the system management apparatus extracts thestorage areas allocated to the plurality of computers from the computerexecution job information, and extracts a hard disk unit group to whichthe storage area belongs to create a first hard disk unit group controlschedule table using information about the storage areas allocated tothe plurality of computers, information about the hard disk unit groupto which the storage area belongs, and a start time and a stop time ofeach of the computers.
 4. The computer system according to claim 3,wherein the system management apparatus extracts the start time and thestop time of each of the computers from the running information aboutthe plurality of computers.
 5. The computer system according to claim 4,wherein the system management apparatus extracts a run time, arepetitive computation number, and an interval for outputting acomputation result from the computer execution job information, andcalculates an output time for the computation result to the hard diskunit group to which the storage area allocated to each of the pluralityof computers belongs on the basis of the extracted information to createa second hard disk unit group control schedule table.
 6. The computersystem according to claim 5, wherein the system management apparatuscombines the first hard disk unit group control schedule table with thesecond hard disk unit group control schedule table to create a thirdhard disk unit group control schedule table.
 7. The computer systemaccording to claim 6, wherein the system management apparatus searchesfor a time zone in which simultaneous running hard disk unit groupsexceeding a predetermined number of simultaneous running hard disk unitgroups run on the basis of the third hard disk unit group controlschedule table, extracts a corresponding time zone, correspondingsimultaneous running hard disk unit groups, and simultaneous operatinglogical storage areas in the simultaneous running hard disk unit groups,selects a number of simultaneous running hard disk unit groups that hasexceeded the predetermined number of simultaneous running hard disk unitgroups from among the simultaneous running hard disk unit groups, andnotifies the storage apparatus of the extracted simultaneous runninghard disk unit groups, the selected number of simultaneous running harddisk unit groups that has exceeded the predetermined number ofsimultaneous running hard disk unit groups, and simultaneous operatinglogical storage areas in the simultaneous running hard disk unit groups,and the storage apparatus reallocates the simultaneous operating logicalstorage areas in the selected simultaneous running hard disk unit groupsexceeding the predetermined number of simultaneous running hard diskunit groups, which is notified by the system management apparatus, to asimultaneous running hard disk unit group other than the selected numberof simultaneous running hard disk unit groups that has exceeded thepredetermined number of simultaneous running hard disk unit groups totransfer data in the reallocated logical storage areas to the hard diskunit group having been designated as the relocation destination.
 8. Thecomputer system according to claim 7, wherein when the number ofsimultaneous running hard disk unit groups that has exceeded thepredetermined number of simultaneous running hard disk unit groups areselected, the system management apparatus preferentially startsselection from a hard disk unit group with the minimum logical storagearea out of the corresponding simultaneous running hard disk unitgroups. 9-20. (canceled)
 21. A computer system, comprising: a pluralityof computers; a storage apparatus having a plurality of hard disk unitsand being connected to the plurality of computers; and a systemmanagement apparatus connected to the plurality of computers and thestorage apparatus, wherein the storage apparatus controls a data writeoperation and a data read operation between the computers and the harddisk units, and controls on/low states of a plurality of power suppliesof the plurality of hard disk units on a group basis with the groupincluding one or more hard disk units, and wherein the system managementapparatus collects running information about the plurality of computersand computer execution job information for each computer, and determinesan on/low time of the power supplies of the plurality of hard disk unitson the group basis to record the collected information and the on/lowtime of the power supplies on the group basis.
 22. The computer systemaccording to claim 21, wherein the storage apparatus turns on/low thepower supplies of the plurality of hard disk units using the on/low timeof the power supplies recorded by the system management apparatus on thegroup basis.
 23. The computer system according to claim 21, wherein thestorage apparatus defines one or more logical storage areas using thegroup of the hard disk units, and allocates the storage areas to theplurality of computers, and the system management apparatus extracts thestorage areas allocated to the plurality of computers from the computerexecution job information, and extracts a hard disk unit group to whichthe storage area belongs to create a first hard disk unit group powersupply control schedule table using information about the storage areasallocated to the plurality of computers, information about the hard diskunit group to which the storage area belongs, and a start time and astop time of each of the computers.
 24. The computer system according toclaim 23, wherein the system management apparatus extracts the starttime and the stop time of each of the computers from the runninginformation about the plurality of computers.
 25. The computer systemaccording to claim 4, wherein the system management apparatus extracts arun time, a repetitive computation number, and an interval foroutputting a computation result from the computer execution jobinformation, and calculates an output time for the computation result tothe hard disk unit group to which the storage area allocated to each ofthe plurality of computers belongs on the basis of the extractedinformation to create a second hard disk unit group control scheduletable.
 26. The computer system according to claim 25, wherein the systemmanagement apparatus combines the first hard disk unit group controlschedule table with the second hard disk unit group control scheduletable to create a third hard disk unit group control schedule table. 27.The computer system according to claim 26, wherein the system managementapparatus searches for a time zone in which simultaneous running harddisk unit groups exceeding a predetermined number of simultaneousrunning hard disk unit groups run on the basis of the third hard diskunit group control schedule table, extracts a corresponding time zone,corresponding simultaneous running hard disk unit groups, andsimultaneous operating logical storage areas in the simultaneous runninghard disk unit groups, selects a number of simultaneous running harddisk unit groups that has exceeded the predetermined number ofsimultaneous running hard disk unit groups from among the simultaneousrunning hard disk unit groups, and notifies the storage apparatus of theextracted simultaneous running hard disk unit groups, the selectednumber of simultaneous running hard disk unit groups that has exceededthe predetermined number of simultaneous running hard disk unit groups,and simultaneous operating logical storage areas in the simultaneousrunning hard disk unit groups, and the storage apparatus reallocates thesimultaneous operating logical storage areas in the selectedsimultaneous running hard disk unit groups exceeding the predeterminednumber of simultaneous running hard disk unit groups, which is notifiedby the system management apparatus, to a simultaneous running hard diskunit group other than the selected number of simultaneous running harddisk unit groups that has exceeded the predetermined number ofsimultaneous running hard disk unit groups to transfer data in thereallocated logical storage areas to the hard disk unit group havingbeen designated as the relocation destination.
 28. The computer systemaccording to claim 27, wherein when the number of simultaneous runninghard disk unit groups that has exceeded the predetermined number ofsimultaneous running hard disk unit groups are selected, the systemmanagement apparatus preferentially starts selection from a hard diskunit group with the minimum logical storage area out of thecorresponding simultaneous running hard disk unit groups.
 29. A systemmanagement apparatus comprising: a storage apparatus having a pluralityof hard disk units, a storage apparatus for controlling a data writeoperation and a data read operation between a plurality of computers andthe hard disk units and for controlling rotational speeds of datastorage media of the plurality of hard disk units on a group basis,wherein the system management apparatus is connected to the plurality ofcomputers and the storage apparatus, and collecting running informationabout the plurality of computers and computer execution job informationfor each computer, and determining various rotational speeds of the datastorage media of the plurality of hard disk units on the group basis torecord the collected information and various rotational speeds on thegroup basis.
 30. The system management apparatus according to claim 29,wherein the system management apparatus is a computer management serverand a storage management server.
 31. A storage apparatus, comprising aplurality of hard disk units, the apparatus being connected to aplurality of computers and a system management apparatus, controlling adata write operation and a data read operation between the plurality ofcomputers and the plurality of hard disk units, and controllingrotational speeds of data storage media of the plurality of hard diskunits on a group basis with the group including one or more hard diskunits to control the rotational speeds of the data storage media of theplurality of hard disk units using various rotational speeds on thegroup basis recoded by the system management apparatus.
 32. The storageapparatus according to claim 31, wherein the system management apparatusis incorporated in the storage apparatus.